Modular Gland Arrangements For A Plug Valve
Insert elements that may be positioned within a high pressure plug valve. The elements have two or more recessed grooves formed around the fluid opening of the elements. The grooves are spaced from one another. A seal is placed in one and only one of the grooves. As wear occurs, the seal is relocated to one of the other grooves. Instead of a series of spaced grooves in a single insert element, a kit may be formed from two or more otherwise identical insert elements, each with a single recessed groove at a different position around the fluid opening.
This application claims the benefit of U.S. Provisional Application Ser. No. 62/379,462, filed Aug. 25, 2016, the entire contents of which are incorporated herein by reference.
SUMMARYThe present invention is directed to a valve comprising a body, a rotatable plug element, and plurality of insert elements. The body comprises a flow passage including an inlet passage and an outlet passage, and an enlarged internal chamber intersecting the flow passage. The rotatable plug element is positioned within the chamber and has a fluid passage extending therethrough. The plurality of insert elements are positioned within the chamber and cooperate to at least partially surround the plug element. Each insert element has a fluid opening extending therethrough and each has a first endless groove surrounding the fluid opening and a second endless groove surrounding the first groove. One and only one seal is positioned in a selected one of the first and second grooves of each insert.
The present invention is also directed to a kit comprising a valve body, a flow passage, a rotatable plug element, a plurality of first insert elements, and a plurality of second insert elements. The valve body comprises a flow passage that includes an inlet passage and an outlet passage, and an enlarged internal chamber that intersects the flow passage. The rotatable plug element is positioned within the chamber and has a fluid passage extending therethrough. The plurality of first insert elements are sized to surround the plug element within the chamber. Each of the first insert elements has a fluid opening extending therethrough and an endless groove surrounding that fluid opening. The plurality of second insert elements are sized to surround the plug element within the chamber. Each second insert element has a fluid opening extending therethrough, an endless groove surrounding that fluid opening, and a size and shape that matches that of the corresponding first insert element. The endless groove of each first insert element would fully surround or be fully surrounded by the endless groove of its corresponding second insert element if those insert elements were superimposed.
High pressure plug valves are typically used in oil and gas operations to control the flow of fluid throughout piping systems. The valve has a flow passage that may be selectively opened and closed in order to control the flow of fluid through the valve. Plug valves used in high pressure oil and gas operations must be able to withstand fluid pressures up to at least 22,500 pounds per square inch. However, the plug valves are typically used with fluid pressures around 15,000 pounds per square inch.
Turning now to
The plug valve 10 further comprises a rotatable plug element 22 positioned within the internal chamber 16. The plug element 22 is secured within the chamber 16 by a retaining nut 23. A fluid passage 24 extends through the plug element 22. A pair of journals 26 and 28 are rigidly attached to opposite sides of the plug element 22 and extend out a top surface 30 and a bottom surface 32 of the body 12. The plug element 22 is rotated by rotating the journals 26 and 28.
To open the plug valve 10 such that fluid may flow through the flow-passage 14, the plug element 22 is rotated so that its fluid passage 24 is in-line with the flow passage 14, To close the plug valve 10 such that fluid may not flow through the flow passage 14, the plug element 22 is rotated so that its fluid passage 24 is not in-line with the flow passage 14.
The plug valve 10 further comprises a plurality of insert elements 34 positioned within the chamber 16 and cooperating to at least partially surround the plug element 22. Each plug valve 10 holds at least two insert elements 34. The insert elements 34 have an inner surface 36 and an outer surface 38. The inner surface 36 surrounds the plug element 22 and the outer surface 38 engages with the inner walls of the chamber 16. A fluid opening 40 interconnects the inner and outer surfaces 36 and 38 and has a fully closed cross-sectional profile. The fluid openings 40 are in-line with the flow passage 14 when the elements 34 are positioned within the chamber 16.
The insert elements 34 each comprise an endless groove 42 surrounding the fluid opening 40, An annular seal 44 may be positioned within the groove 42. The seal 44 blocks fluid from leaking into the internal chamber 16. The internal walls of the chamber 16 directly across from the position of the seals 44 act as sealing surfaces 46 for the seals 44 when the insert elements 34 are positioned within the chamber 16.
The plug valve 10 shown in
With reference to
A plurality of insert elements 58 are shown positioned around a rotatable plug element 60 within the internal chamber 56. The outer surfaces 62 of the insert elements 58 are not tapered so that they may be closely received within the non-tapered chamber 56. The insert elements 58 have a concave inner surface 64 and a spaced outer surface 62 that is congruent with the curved side of a cylinder.
The insert elements 58 each comprises an endless groove 66 surrounding a fluid opening 68, An annular seal 70 may be positioned within the groove 66 to prevent fluid from leaking into the internal chamber 56. The internal walls of the chamber 56 directly across from the position of the seals 70 act as sealing surfaces 72 for the seals 70 when the insert elements 58 are positioned within the chamber go.
With reference to
The present invention is directed to a system including a plurality of insert elements 34 or 58 that permit the seals 44 or 70 to be relocated within the chamber 16 or 56 over time. Relocating the seals 44 or 70 also relocates the sealing surfaces 46 or 72. Thus, if the original sealing surfaces 46 or 72 suffer erosion, the seals 44 or 70 can be moved to engage with different sealing surfaces 46 or 72 in the chamber 16 or 56. Such relocation will help extend the life of the plug valve 10 or 50.
Turning now to
A fluid opening 106 is formed in the center of the elements 100. A first endless groove 108 is formed in the outer surface 102 surrounding the opening 106. A second endless groove 110 formed in the outer surface 102 surrounds the first groove 108, and a third endless groove 112 formed in the outer surface 102 surrounds the second groove 110. Each of the grooves 108, 110, and 112 is characterized by two side walls 114 joined by a base 116.
The grooves 108, 110, and 112 follow a circular path around the fluid opening 106. However, each of the grooves 108, 110, and 112 may vary in size and shape and follow a path of any shape or size desired around the fluid opening 106. For example, one or all of the grooves 108, 110, or 112 may follow a rectangular path around the fluid opening 106.
Turning now to
With reference to
In operation, the first seal 118A is positioned within the first groove 108 of the insert elements 100. The insert elements 100 are positioned within the chamber 56 so that they surround the plug element 60 and their fluid openings 106 are in-line with the flow passage 54 (
High pressure fluid is passed through the plug valve 50. Over time, the sealing surfaces 72 for the first seals 118A will start to erode. If the first seals 118A start to leak, the flow of fluid into the plug valve 50 is stopped. The insert elements 100 are removed from the chamber 56 and the first seals 118A are removed from the first grooves 108. The second seals 118B are positioned in the second grooves 110 and the insert elements 100 are re-positioned within the chamber 56 (
As the sealing surfaces 72 experience erosion, the second seals 118B may begin to leak. The flow of fluid in the plug valve 50 is again stopped and the insert elements 100 are removed. The second seals 118B are removed from the insert elements 100 and the third seals 118C are positioned within the third grooves 112. The insert elements 100 are then re-positioned within the chamber 56 (
The operator may choose any order of positioning a single seal within any single one of the grooves desired. The order of operation described above is non-limiting and is just one method of using the inserts 100. For example, the operator may start the operation by positioning the third seal 118C in the third groove 112, rather than starting with the first seal 118A to the first groove 108.
The same methods described above may be employed using an insert element 100 having only two grooves or having more than three grooves. Once the final seal 118 no longer seals properly against its sealing surface 72, the plug valve 50 will likely need to be replaced. Because each plug valve 10 and go uses at least two different insert elements 100, the above method may be employed at different times for each element 100, depending on the wear incurred by the sealing surface 72 for the seal 118 within each element.
Turning now to
Except as described hereafter, the inserts 200 are identical in size and shape to the inserts 100. The inserts 200 include a first insert element 202, a second insert element 204, and a third insert element 206. Each of the insert elements 202, 204, and 206 has a single endless groove 212, 214, or 216 formed in its outer surface 208 and surrounding its fluid opening 218. Each of the grooves 212, 214, and 216 is characterized by two side walls 220 joined by a base 222.
The first insert element 202 has a first groove 212. The second insert element 204 has a second groove 214 that is outwardly spaced from the position of the first groove 212 in the first insert element 202. The third insert element 206 has a third groove 216 that is outwardly spaced from the position of the second groove 214. The first groove 212 is positioned nearest the fluid opening 218, and the third groove 216 is positioned nearest the edge of its respective insert element.
Each of the grooves 212, 214, and 216 is configured so that it would be fully surrounded or fully surround one another if the insert elements 202, 204, and 206 were superimposed. Like the grooves 108, 110, and 112 (
Turning nowr to
In operation, the operator will install the first insert elements 202 into the chamber 56 so that they surround the plug element 60 and their fluid openings 218 are in-line with the flow passage 54 (
High pressure fluid is passed through the plug valve 50. Over time, the sealing surfaces 72 for the first seals 224A will start to erode. If the first seals 224A start to leak, the flow of fluid into the plug valve 50 is stopped. The first insert elements 202 are removed from the chamber 56 and replaced with the second insert elements 204 (
Because the position of the second seals 224B on the second insert elements 204 is spaced from that of the first seals 224A on the first insert elements 202, the second seals 224B will have new non-eroded sealing surfaces 72 in the chamber 56. Thus, the second seals 224B will offer enhanced resistance from leakage into the chamber 56.
As the sealing surfaces 72 experience erosion, the second seals 224B may begin to leak. The flow of fluid in the plug valve 50 is again stopped and the insert elements 204 are removed and replaced with the third insert elements 206 (
The operator may choose any order of using the insert elements 200 desired. The order of operation described above is non-limiting and is just one method of using the insert elements 200. For example, the operator may start the operation by positioning the third insert element 206 into the chamber 56, rather than starting by positioning the first insert element 202 into the chamber 56.
The same methods described with reference to insert elements 200 may be employed using only two different insert elements 200 or more than three different insert elements 200. Once the seals 224 on the final insert elements no longer seal properly, the plug valve 50 will likely need to be replaced. Because each plug valve 10 or 50 uses at least two different insert elements 200, the above method may be employed at different times for each element 200, depending on the wear incurred by the sealing surfaces 46 or 72 for the seal 224 within each element.
Various modifications can be made in the design and operation of the present, invention without departing from the spirit thereof. Thus, while the principle preferred construction and modes of operation of the invention have been explained in what is now considered to represent its best embodiments, which have been illustrated and described, it should be understood that the invention may be practiced otherwise than as specifically illustrated and described.
Claims
1. A valve, comprising:
- a body, comprising: a flow passage including an inlet passage and an outlet passage; and an enlarged internal chamber intersecting the flow passage;
- a rotatable plug element positioned within the chamber, having a fluid passage extending therethrough; and
- a plurality of insert elements positioned within the chamber and cooperating to at least partially surround the plug element, each insert element having a fluid opening extending therethrough and each having a first endless groove surrounding the fluid opening and a second endless groove surrounding the first groove, in which one and only one seal is positioned in a selected one of the first or second grooves of each insert,
2. The valve of claim 1 further comprising a third endless groove surrounding the flow passage and spaced from the first and second groove, in which a seal not positioned within the third groove.
3. The valve of claim 1 in which the first and second grooves are characterized by two side walls joined by a base.
4. The valve of claim 1 in which each of the first and second insert elements has a concave inner surface and a spaced outer surface, the fluid opening interconnecting the inner and outer surfaces having a fully closed cross-sectional profile,
5. The valve of claim 1 in which the first and second grooves are shaped differently,
6. The valve of claim 1 in which the first and second grooves each follow a circular path around the fluid opening.
7. The valve of claim 1 in which each insert element has an outer surface, a portion of which is congruent with a portion of the curved surface of a cone.
8. The valve of claim 1 in which each insert element has an outer surface, a portion of which is congruent with a portion of the curved side surface of a cylinder,
9. A system comprising:
- the valve of claim 1; and
- a fluid having a pressure of at least 15,000 pounds per square inch within at least a portion of the flow passage.
10. A method of using the valve of claim 1, comprising:
- removing at least one of the plurality of insert elements from the valve;
- removing the first seal from the at least one insert element;
- positioning a second seal within the groove of the at least one insert element from which no first seal was removed; and
- positioning the at least one insert element into the chamber of the valve.
11. A kit comprising:
- a valve body, comprising: a flow passage including an inlet passage and an outlet passage; and an enlarged internal chamber intersecting the flow passage;
- a rotatable plug element positioned within the chamber, having a fluid passage extending therethrough;
- a plurality of first insert elements sized to surround the plug element within the chamber, each first insert element having a fluid opening extending therethrough and an endless groove surrounding that fluid opening; and
- a plurality of second insert elements sized to surround the plug element within the chamber, each second insert, element having a fluid opening extending therethrough, an endless groove surrounding that fluid opening;
- in which the endless groove of each first insert element would hilly surround or be fully surrounded by the endless groove of its corresponding second insert element if those insert elements were superimposed,
12. The kit of claim 11 further comprising a plurality of third insert, elements sized to surround the plug element within the chamber, each third insert element having a fluid opening extending therethrough, and an endless groove surrounding that fluid opening, in which the endless groove of each third insert element would fully surround or be fully surrounded by the endless groove of any of its corresponding first and second insert, elements if those insert elements were superimposed.
13. The kit of claim 11 in which the first and second grooves are characterized by two side walls joined by a base.
14. The kit of claim 11 in which each of the first and second insert elements has a concave inner surface and a spaced outer surface, the fluid opening interconnecting the inner and outer surfaces having a fully closed cross-sectional profile.
15. The kit of claim 11 in which the first and second grooves are shaped differently.
16. The kit of claim 11 in which the first and second inserts elements have matching sizes and shapes.
17. The kit of claim 11 in which each of the first and second insert elements has an outer surface, a portion of which is congruent with a portion of the curved surface of a cone.
18. The kit of claim 11 in which each insert element has an outer surface, a portion of which is congruent with a portion of the curved side surface of a cylinder.
19. A system comprising:
- the kit of claim 11; and
- a fluid having a pressure of at least 15,000 pounds per square inch within at least a portion of the flow passage.
20. A method of using the kit of claim 11, comprising:
- positioning a first seal within the groove of at least, one of the plurality of first insert elements;
- placing the at least one first insert element within the chamber;
- removing the at least one first insert element from the chamber;
- positioning a second seal within the groove of at least one of the plurality of second insert elements; and
- placing the at least one second insert element within the chamber.
Type: Application
Filed: Aug 24, 2017
Publication Date: Mar 1, 2018
Patent Grant number: 10539132
Inventor: Kelcy Jake Foster (Ardmore, OK)
Application Number: 15/685,178